How Cell Phones Work

How Cell Phones Work

An Important Technology • Cellular telephony is one of the fastest growing technologies on the planet. • Presently, we are starting to see the third generation of the cellular phones coming to the market. • New phones allow users to do much more than hold phone conversations.

Beyond Voice • Store contact information • Make task/to-do lists • Keep track of appointments • Calculator • Send/receive email • Send/receive pictures • Send/receive video clips • Get information from the internet • Play games • Integrate with other devices (PDA’s, MP3 Players, etc.)

Basic Concept • Cellular system developed to provide mobile telephony: telephone access “anytime, anywhere.” • First mobile telephone system was developed and inaugurated in the U.S. in 1945 in St. Louis, MO. • This was a simplified version of the system used today.

System Architecture • A base station provides coverage (communication capabilities) to users on mobile phones within its coverage area. • Users outside the coverage area receive/transmit signals with too low amplitude for reliable communications. • Users within the coverage area transmit and receive signals from the base station. • The base station itself is connected to the wired telephone network.

Entire Coverage Area First Mobile Telephone System One and only one high power base station with which all users communicate. Normal Telephone System Wired connection

Problem with Original Design • Original mobile telephone system could only support a handful of users at a time…over an entire city! • With only one high power base station, users phones also needed to be able to transmit at high powers (to reliably transmit signals to the distant base station). • Car phones were therefore much more feasible than handheld phones, e.g., police car phones.

The Core Idea: Cellular Concept • The core idea that led to today’s system was the cellular concept. • The cellular concept: multiple lower-power base stations that service mobile users within their coverage area and handoff users to neighboring base stations as users move. Together base stations tessellate the system coverage area.

Cellular Concept • Thus, instead of one base station covering an entire city, the city was broken up into cells, or smaller coverage areas. • Each of these smaller coverage areas had its own lower-power base station. • User phones in one cell communicate with the base station in that cell.

3 Core Principles • Small cells tessellate overall coverage area. • Users handoff as they move from one cell to another. • Frequency reuse.

Tessellation • Some group of small regions tessellate a large region if they over the large region without any gaps or overlaps. • There are only three regular polygons that tessellate any given region.

Tessellation (Cont’d) • Three regular polygons that always tessellate: • Equilateral triangle • Square • Regular Hexagon Triangles Squares Hexagons

Circular Coverage Areas • Original cellular system was developed assuming base station antennas are omnidirectional, i.e., they transmit in all directions equally. Users located outside some distance to the base station receive weak signals. Result: base station has circular coverage area. Weak signal Strong signal

Circles Don’t Tessellate • Thus, ideally base stations have identical, circular coverage areas. • Problem: Circles do not tessellate. • The most circular of the regular polygons that tessellate is the hexagon. • Thus, early researchers started using hexagons to represent the coverage area of a base station, i.e., a cell.

Thus the Name Cellular • With hexagonal coverage area, a cellular network is drawn as: • Since the network resembles cells from a honeycomb, the name cellular was used to describe the resulting mobile telephone network. Base Station

Handoffs • A crucial component of the cellular concept is the notion of handoffs. • Mobile phone users are by definition mobile, i.e., they move around while using the phone. • Thus, the network should be able to give them continuous access as they move. • This is not a problem when users move within the same cell. • When they move from one cell to another, a handoff is needed.

A Handoff • A user is transmitting and receiving signals from a given base station, say B1. • Assume the user moves from the coverage area of one base station into the coverage area of a second base station, B2. • B1 notices that the signal from this user is degrading. • B2 notices that the signal from this user is improving.

A Handoff (Cont’d) • At some point, the user’s signal is weak enough at B1 and strong enough at B2 for a handoff to occur. • Specifically, messages are exchanged between the user, B1, and B2 so that communication to/from the user is transferred from B1 to B2. B2 B1

Frequency Reuse • Extensive frequency reuse allows for many users to be supported at the same time. • Total spectrum allocated to the service provider is broken up into smaller bands. • A cell is assigned one of these bands. • This means all communications (transmissions to and from users) in this cell occur over these frequencies only.

Frequency Reuse (Cont’d) • Neighboring cells are assigned a different frequency band. • This ensures that nearby transmissions do not interfere with each other. • The same frequency band is reused in another cell that is far away. • This large distance limits the interference caused by this co-frequency cell.

Example of Frequency Reuse Cells using the same frequencies

Multiple Access in Cellular Networks

Multiple Transmitters, One Receiver • In many wireless systems, multiple transmitters attempt to communicate with the same receiver. • For example, in cellular systems. • Cell phones users in a local area typically communicate with the same cell tower. • How is the limited spectrum shared between these local transmitters?

Multiple Access Method • In such cases, system adopts a multiple access policy. • Three widely-used policies: • Frequency Division Multiple Access (FDMA) • Time Division Multiple Access (TDMA) • Code Division Multiple Access (CDMA)

FDMA • In FDMA, we assume that a base station can receive radio signals in a given band of spectrum, i.e., a range of continuous frequency values. • The band of frequency is broken up into smaller bands, i.e., subbands. • Each transmitter (user) transmits to the base station using radio waves in its own subband. Cell Phone User 1 Cell Phone User 2 : : Cell Phone User N Frequency Subbands Time

FDMA (Cont’d) • A subband is also a range of continuous frequencies, e.g., 824 MHz to 824.1 MHz. • The width of this subband is 0.1 MHz = 100 KHz. • When a users is assigned a subband, it transmits to the base station using a sine wave with the center frequency in that band, e.g., 824.05 MHz.

FDMA (Cont’d) • When the base station is tuned to the frequency of a desired user, it receives no portion of the signal transmitted by another in-cell user (using a different frequency). • This way, the multiple local transmitters within a cell do not interfere with each other.

TDMA • In pure TDMA, base station does not split up its allotted frequency band into smaller frequency subbands. • Rather it communicates with the users one-at-a-time, i.e., “round robin” access. … User 2 User 3 User 1 Frequency Bands User N Time

TDMA (Cont’d) • Time is broken up into time slots, i.e., small, equal-length intervals. • Assume there are some n users in the cell. • Base station groups n consecutive slots into a frame. • Each user is assigned one slot per frame. • This slot assignment stays fixed as long as the user communicates with the base station (e.g., length of the phone conversation).

TDMA (Cont’d) • Example of TDMA time slots for n = 10. • In each time slot, the assigned user transmits a radio wave using a sine wave at the center frequency of the frequency band assigned to the base station. … … … User 10 User 1 User 1 User 1 User 2 User 10 Slot Time Frame

Hybrid FDMA/TDMA • The TDMA used by real cellular systems (like AT&T’s) is actually a combination of FDMA/TDMA. • Base station breaks up its total frequency band into smaller subbands. • Base station also divides time into slots and frames. • Each user is now assigned a frequency and a time slot in the frame.

… User 31 User 32 User 40 … User 21 User 22 User 30 … User 11 User 12 User 20 … User 1 User 2 User 10 Hybrid FDMA/TDMA (Cont’d) Assume a base station divides its frequency band into 4 subbands and time into 10 slots per frame. … … User 31 User 32 User 40 Frequency Subband 4 … … Frequency Subband 3 User 21 User 22 User 30 … … Frequency Subband 2 User 11 User 12 User 20 … … User 1 User 2 User 10 Frequency Subband 1 Frame Time

CDMA • CDMA is a more complicated scheme. • Here all users communicate to the receiver at the same time and using the same set of frequencies. • This means they may interfere with each other. • The system is designed to control this interference. • A desired user’s signal is deciphered using a unique code assigned to the user. • There are two types of CDMA methods.

CDMA Method 1: Frequency Hopping • First CDMA technique is called frequency hopping. • In this method each user is assigned a frequency hopping pattern, i.e., a fixed sequence of frequency values. • Time is divided into slots. • In the first time slot, a given user transmit to the base station using the first frequency in its frequency hopping sequence.

Frequency Hopping (Cont’d) • In the next time interval, it transmits using the second frequency value in its frequency hop sequence, and so on. • This way, the transmit frequency keeps changing in time.

Second Type of CDMA: Direct Sequence • This is a more complicated version of CDMA. • Basically, each in-cell user transmits its message to the base station using the same frequency, at the same time. • Here signals from different users interfere with each other. • But the user distinguishes its message by using a special, unique code. • This code serves as a special language that only the transmitter and receiver understand. • Others cannot decipher this language.

Final Points on FDMA/TDMA/CDMA • When users are in the middle of a phone call, the system uses FDMA/TDMA/CDMA to give them access. • But there are only so many frequencies, time-slots, or codes available to share between users in a cell. • If we divide the frequency into too many bands, or use too many time slots, or too many codes, • the quality of speech heard by the end user will be unsatisfactory.

Channels • Channel is a general term which refers to a frequency in an FDMA system, a timeslot/frequency combination in TDMA, or a code in CDMA. • This way, a base station has a fixed number of channels and can support only that many simultaneous users.

Random Access: Another Important Multiple Access Method

Motivating Random Access Channels • As mentioned earlier, FDMA/TDMA/CDMA are used when users are engaged in a phone call. • Before being assigned a frequency, timeslot, or code (i.e., a channel), a user has to ask the base station if it has a channel leftover to assign this user. • In other words, the user has to have some other way of communicating with the base station.

Motivating Random Access • Of all the frequencies available at a base station, a prescribed portion of them are set aside for this purpose. • These frequencies are called control channels, as opposed to the rest of the frequencies in cell, which are called voice channels. • A user will transmit a signal to the base station on a control channel basically saying, “I’m here and I’d like to talk to you.”

Random Access: Failure • There maybe other users who do this at the same time using the same frequency. • If they do, the signals will interfere with each other and the base station will not receive anything. • This indicates a failure (aka collision), when this happens, each user will backoff for some random amount of time and try again. • Since they backoff for a random amount of time, chances are they won’t retry at the same time.

Random Access: Success • If only one user transmits, then the base station will receive the user’s signals and respond to it by saying, “Okay you can talk to me, tune into this other channel and tell me what you want.” • The user will then tune this channel and be able to exclusively transmit and receive signals to the base station.

Random Access: Success (Cont’d) • This new channel assigned to the user is also a control channel. • Using this channel the user can then send a signal that says for example “I want to make a phone to this phone number.” • To which the base station will respond by assigning the user a voice channel, if there are some available.

Random Access Summary • This type of competing access method is called random access. • There are different rules followed by users participating in random access.

AMPS: A Model for Learning about Cellular Networks

Complete Cellular Network A group of local base stations are connected (by wires) to a mobile switching center (MSC). MSC is connected to the rest of the world (normal telephone system). MSC Public (Wired) Telephone Network MSC MSC MSC

Mobile Switching Centers • Mobile switching centers control and coordinate the cellular network. • They serve as intermediary between base stations that may be handing off users between each other. • Base stations communicate with each via the MSC. • MSC keep track of cell phone user subscription. • MSC connects to the wired phone network (rest of the world).

The AMPS System • AMPS uses FDMA: a service provider is given license to 832 frequencies to use across a geographic region, say a city. • Service provider chops up the city into cells. • Each cell is roughly 10 square miles. • Each cell has a base station that consists of a tower and a small building containing radio equipment.

The AMPS System (Cont’d) • AMPS uses frequency duplexing, i.e., each cell phone uses one frequency to transmit on and another frequency to receive on. • Total 832 channels are divided into half. • One half is used on the uplink, i.e., used by cell phones to transmit to the base station. • The other half is used on the downlink, i.e., used by the base to transmit to cell phone users.

How Cell Phones Work